Alan D. Springer scite author profile

A memory model is proposed in which information enters an initial structuralchemical format within fractions of a second. Experimental amnesia is viewed as a failure to retrieve information from long-term memory rather than a failure of the information to be consolidated in long-term memory. Consolidation and retrieval failure explanations of experimental amnesia are found to differ primarily on the issue of recovery of memory. The nature of experimental amnesia paradigms is such that the consolidation position can never be supported; it may only be refuted by an occurrence of recovery of memory or left as an unresolved issue by a lack of recovery. The use of noncontingent stimuli to induce recovery from amnesia has been successful in several instances, thereby supporting the retrieval failure hypothesis. Success in producing amnesia for reactivated "old" memories further corroborates the retrieval position. Arguments that effectively delivered, high-intensity or high-dosage amnestic agents will disrupt consolidation beg the question and are presently without any empirical support. Two-process theories proposing both retrieval and consolidation failures are presently neither necessary nor parsimonious.

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Development of the primate area of high acuity, 3: Temporal relationships between pit formation, retinal elongation and cone packing

Springer

Hendrickson

2005

Vis Neurosci

101

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By establishing an avascular, highly elastic, region within the fetal area of high acuity (AHA), the developing primate eye has created a unique substrate on which the mechanical forces of intraocular pressure (IOP) and growth-induced retinal stretch (stretch) can act. We proposed (Springer & Hendrickson, 2004b) that these forces generate both the pit and high cone density found in the adult AHA. In this paper, we use quantitative measures to determine the temporal relationships between nasal and temporal retinal elongation, changes in pit depth, cone packing, and cone morphology over M. nemestrina retinal development. Retinal length increased rapidly to about 105 days postconception (dpc; Phase 1) and then elongation virtually ceased (Phase 2) until just after birth (180 dpc). Retinal elongation due to stretch resumed during Phase 3 until approximately 315 dpc (4-5 months), after which time the retina appeared mature (Phase 4). The pit appeared during the quiescent Phase 2, suggesting that IOP acts, in conjunction with molecular changes in the inner retina, on the highly elastic, avascular, AHA to generate a deep, narrow pit and causes inner retinal cellular displacements. Subsequently (Phase 3), the pit widened, became 50% shallower and central inner retinal lamina thinned slightly due to a small amount of retinal stretch occurring in the AHA. Centripetal movement of cones was minimal until just after birth when the pit reached 88% of its maximal depth. Accelerated cone packing during Phase 3 was temporally correlated with increased stretch.

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Development of the primate area of high acuity. 1. Use of finite element analysis models to identify mechanical variables affecting pit formation

2004

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Most primate retinas have an area dedicated for high visual acuity called the fovea centralis. Little is known about specific mechanisms that drive development of this complex central retinal specialization. The primate area of high acuity (AHA) is characterized by the presence of a pit that displaces the inner retinal layers. Virtual engineering models were analyzed with finite element analysis (FEA) to identify mechanical mechanisms potentially critical for pit formation. Our hypothesis is that the pit emerges within the AHA because it contains an avascular zone (AZ). The absence of blood vessels makes the tissue within the AZ more elastic and malleable than the surrounding vascularized retina. Models evaluated the contribution to pit formation of varying elasticity ratios between the AZ and surrounding retina, AZ shape, and width. The separate and interactive effects of two mechanical variables, intraocular pressure (IOP) and ocular growth-induced retinal stretch, on pit formation were also evaluated. Either stretch or IOP alone produced a pit when applied to a FEA model having a highly elastic AZ surrounded by a less elastic region. Pit depth and width increased when the elasticity ratio increased, but a pit could not be generated in models lacking differential elasticity. IOP alone produced a deeper pit than did stretch alone and the deepest pit resulted from the combined effects of IOP and stretch. These models predict that the pit in the AHA is formed because an absence of vasculature makes the inner retinal tissue of the AZ very deformable. Once a differential elasticity gradient is established, pit formation can be driven by either IOP or ocular growth-induced retinal stretch.

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Induced recovery of memory in rats following electroconvulsive shock

Miller

Springer

1972

Physiology & Behavior

141

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Development of the primate area of high acuity. 2. Quantitative morphological changes associated with retinal and pars plana growth

Springer

Hendrickson

2004

Vis Neurosci

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Mechanisms underlying the development of the primate area of high acuity (AHA) remain poorly understood. Finite-element models have identified retinal stretch and intraocular pressure (IOP) as possible mechanical forces that can form a pit (Springer & Hendrickson, 2004). A series of Macaca nemestrina monkey retinas between 68 days postconception (dpc) and adult were used to quantify growth and morphological changes. Retinal and pars plana length, optic disc diameter, disc-pit distance, and inner and outer retinal laminar thickness were measured over development to identify when and where IOP or stretch might operate. Horizontal optic disc diameter increased 500 mum between 115 dpc and 2 months after birth when it reached adult diameter. Disc growth mainly influences the immediate surrounding retina, presumably displacing retinal tissue centrifugally. Pars plana elongation also began at 115 dpc and continued steadily to 3-4 years postnatal, so its influence would be relatively constant over retinal development. Unexpectedly, horizontal retinal length showed nonlinear growth, divided into distinct phases. Retinal length increased rapidly until 115 dpc and then remained unchanged (quiescent phase) between 115-180 dpc. After birth, the retina grew rapidly for 3 months and then very slowly into adulthood. The onset of pit development overlapped the late fetal quiescent phase, suggesting that the major mechanical factor initiating pit formation is IOP, not retinal growth-induced stretch. Developmental changes in the thickness of retinal layers were different for inner and outer retina at many, but not all, of the ten eccentricities examined.

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Alan D. Springer

Amnesia, consolidation, and retrieval.

Development of the primate area of high acuity, 3: Temporal relationships between pit formation, retinal elongation and cone packing

Development of the primate area of high acuity. 1. Use of finite element analysis models to identify mechanical variables affecting pit formation

Induced recovery of memory in rats following electroconvulsive shock

Development of the primate area of high acuity. 2. Quantitative morphological changes associated with retinal and pars plana growth

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